Selection and expansion of T cell from untreated patients with CLL: source of cells for immune reconstitution?

BACKGROUND: Lymphocyte-derived malignancies can be treated with combinations of drugs that efficiently eradicate normal and malignant lymphocytes. Lack of T lymphocytes after treatment of B lymphocyte CLL (B-CLL) makes the patients susceptible to serious infections and may limit the benefit of the therapy. The aim of the study was to purify and culture-expand normal T lymphocytes from B-CLL patients prior to therapy. These cells could be frozen and given to the patients in the lymphopenic period post-chemotherapy. METHODS: T lymphocytes were isolated from the mononuclear cell apheresis products from five patients with previously untreated B-CLL. The apheresis products were red-cell depleted by density gradient centrifugation. B-lymphocyte purging was performed by incubating with MAbs to four different B-cell epitopes, followed by magnetic-bead depletion. One round of negative selection removed >90% of the B lymphocytes. The T-lymphocyte enriched cell suspension was cultured for 10/11 days in the presence of IL-2 and the anti-T cell receptor Ab OKT3. In addition, in some cultures anti-CD22 ricin immunotoxin was added. RESULTS: T cells from CLL patients expanded 4.7-21-fold over a 10/11 days culture interval. After culture, CLL cells could no longer be identified by flow cytometric evaluation. The cultured T lymphocytes were predominantly CD8(+), and were capable of lysing autologous CLL cells through a fas-dependent mechanism. DISCUSSION: Selection and expansion of T lymphocytes by this method may represent a strategy for enhancing immunity in the lymphopenic period following CLL treatment.

fas-mediated lysis of chronic lymphocytic leukaemia cells: role of type I versus type II cytokines and autologous fasL-expressing T cells.

Given the known role of the fas cytolytic pathway in B-cell regulation, we evaluated whether fas-fasL interactions might induce chronic lymphocytic leukaemia (CLL) cell death. De novo CLL cells expressed a low level of surface fas, and were not lysed by fasL-bearing cells. CLL cells cultured in media containing the type I cytokines interleukin (IL)-12 or interferon (IFN)-alpha had increased fas expression, and were readily lysed by fasL-bearing cells. In contrast, the type II cytokine IL-4 did not increase CLL cell fas, and abrogated type I cytokine-induced fas up-regulation. With prolonged culture, IL-4 exposed CLL cells expressed an intermediate level of fas; however, such CLL cells were resistant to fas-mediated lysis. These results indicate that IL-4 inhibits fas-mediated killing of CLL cells at the level of both fas receptor expression and post-receptor events. Additionally, we have defined in vitro culture conditions which generate fasL-bearing T cells from CLL patients; such T cells efficiently mediated fas-based lysis of autologous fas-positive CLL cells. We therefore conclude that type I and type II cytokines differentially regulate the fas pathway in CLL cells, and that a combination of type I cytokines and fasL-expressing T cells may represent a new approach to the immunotherapy of CLL.

Specific depletion of alloreactive T cells in HLA-identical siblings: a method for separating graft-versus-host and graft-versus-leukaemia reactions.

Accumulating evidence indicates that alloreactive donor T cells confer both graft-versus-host (GVH) and graft-versus-leukaemia (GVL) reactivity following allogeneic bone marrow transplantation. We have developed a method to deplete alloreactive donor T cells with an immunotoxin targeting the alpha chain of the IL-2 receptor. In patients with chronic myeloid leukaemia and their HLA-identical sibling donors, we measured donor helper T-lymphocyte precursor frequencies (HTLPf) against recipient peripheral blood mononuclear cells (PBMNC; donor versus host), recipient leukaemia cells (donor versus leukaemia) and third-party PBMNC, before and after the depletion. In seven pairs there was a 4.3-fold reduction of donor-versus-host HTLPf (P=0.017), without a significant change in the donor frequencies against third party (P=0.96). In eight further donor-recipient pairs, immunotoxin-depleted donor versus patient PBMNC HTLPf 4.5-fold (mean 1/155,000 before and 1/839,000 after depletion, P=0.007). There was a smaller non-significant 1.8-fold reduction in donor-versus-leukaemia HTLPf from 1/192,000 to 1/334,000 (P=0.19). These results suggest that selective T-cell depletion can significantly deplete donor anti-host reactivity while conserving anti-leukaemia reactivity in HLA-matched donor-recipient pairs.